Currently if task_manager::task::impl::abort preempts before children
are recursively aborted and then the task gets unregistered, we hit
use after free since abort uses children vector which is no
longer alive.
Modify abort method so that it goes over all tasks in task manager
and aborts those with the given parent.
Fixes: #19304.
The ranges_parallelism option is introduced in commit 9b3fd9407b.
Currently, this option works for vnode table repair only.
This patch enables it for tablet repair, since it is useful for
tablet repair too.
Fixes#18383Closesscylladb/scylladb#18385
Since a given tablet belongs to a single shard on both repair master and repair
followers, row level repair code needs to be changed to work on a single
shard for a given tablet. In order to tell the repair followers which
shard to work on, a dst_cpu_id value is passed over rpc from the repair
master.
remove the unused #include headers from repair.hh, as they are not
directly used. after this change, task_manager_module.hh fails to
have access to stream_reason, so include it where it is used.
Signed-off-by: Kefu Chai <kefu.chai@scylladb.com>
Closesscylladb/scylladb#16618
*) Problem:
We have seen in the field it takes longer than expected to repair system tables
like system_auth which has a tiny amount of data but is replicated to all nodes
in the cluster. The cluster has multiple DCs. Each DC has multiple nodes. The
main reason for the slowness is that even if the amount of data is small,
repair has to walk though all the token ranges, that is num_tokens *
number_of_nodes_in_the_cluster. The overhead of the repair protocol for each
token range dominates due to the small amount of data per token range. Another
reason is the high network latency between DCs makes the RPC calls used to
repair consume more time.
*) Solution:
To solve this problem, a small table optimization for repair is introduced in
this patch. A new repair option is added to turn on this optimization.
- No token range to repair is needed by the user. It will repair all token
ranges automatically.
- Users only need to send the repair rest api to one of the nodes in the
cluster. It can be any of the nodes in the cluster.
- It does not require the RF to be configured to replicate to all nodes in the
cluster. This means it can work with any tables as long as the amount of data
is low, e.g., less than 100MiB per node.
*) Performance:
1)
3 DCs, each DC has 2 nodes, 6 nodes in the cluster. RF = {dc1: 2, dc2: 2, dc3: 2}
Before:
```
repair - repair[744cd573-2621-45e4-9b27-00634963d0bd]: stats:
repair_reason=repair, keyspace=system_auth, tables={roles, role_attributes,
role_members}, ranges_nr=1537, round_nr=4612,
round_nr_fast_path_already_synced=4611,
round_nr_fast_path_same_combined_hashes=0, round_nr_slow_path=1,
rpc_call_nr=115289, tx_hashes_nr=0, rx_hashes_nr=5, duration=1.5648403 seconds,
tx_row_nr=2, rx_row_nr=0, tx_row_bytes=356, rx_row_bytes=0,
row_from_disk_bytes={{127.0.14.1, 178}, {127.0.14.2, 178}, {127.0.14.3, 0},
{127.0.14.4, 0}, {127.0.14.5, 178}, {127.0.14.6, 178}},
row_from_disk_nr={{127.0.14.1, 1}, {127.0.14.2, 1}, {127.0.14.3, 0},
{127.0.14.4, 0}, {127.0.14.5, 1}, {127.0.14.6, 1}},
row_from_disk_bytes_per_sec={{127.0.14.1, 0.00010848}, {127.0.14.2,
0.00010848}, {127.0.14.3, 0}, {127.0.14.4, 0}, {127.0.14.5, 0.00010848},
{127.0.14.6, 0.00010848}} MiB/s, row_from_disk_rows_per_sec={{127.0.14.1,
0.639043}, {127.0.14.2, 0.639043}, {127.0.14.3, 0}, {127.0.14.4, 0},
{127.0.14.5, 0.639043}, {127.0.14.6, 0.639043}} Rows/s,
tx_row_nr_peer={{127.0.14.3, 1}, {127.0.14.4, 1}}, rx_row_nr_peer={}
```
After:
```
repair - repair[d6e544ba-cb68-4465-ab91-6980bcbb46a9]: stats:
repair_reason=repair, keyspace=system_auth, tables={roles, role_attributes,
role_members}, ranges_nr=1, round_nr=4, round_nr_fast_path_already_synced=4,
round_nr_fast_path_same_combined_hashes=0, round_nr_slow_path=0,
rpc_call_nr=80, tx_hashes_nr=0, rx_hashes_nr=0, duration=0.001459798 seconds,
tx_row_nr=0, rx_row_nr=0, tx_row_bytes=0, rx_row_bytes=0,
row_from_disk_bytes={{127.0.14.1, 178}, {127.0.14.2, 178}, {127.0.14.3, 178},
{127.0.14.4, 178}, {127.0.14.5, 178}, {127.0.14.6, 178}},
row_from_disk_nr={{127.0.14.1, 1}, {127.0.14.2, 1}, {127.0.14.3, 1},
{127.0.14.4, 1}, {127.0.14.5, 1}, {127.0.14.6, 1}},
row_from_disk_bytes_per_sec={{127.0.14.1, 0.116286}, {127.0.14.2, 0.116286},
{127.0.14.3, 0.116286}, {127.0.14.4, 0.116286}, {127.0.14.5, 0.116286},
{127.0.14.6, 0.116286}} MiB/s, row_from_disk_rows_per_sec={{127.0.14.1,
685.026}, {127.0.14.2, 685.026}, {127.0.14.3, 685.026}, {127.0.14.4, 685.026},
{127.0.14.5, 685.026}, {127.0.14.6, 685.026}} Rows/s, tx_row_nr_peer={},
rx_row_nr_peer={}
```
The time to finish repair difference = 1.5648403 seconds / 0.001459798 seconds = 1072X
2)
3 DCs, each DC has 2 nodes, 6 nodes in the cluster. RF = {dc1: 2, dc2: 2, dc3: 2}
Same test as above except 5ms delay is added to simulate multiple dc
network latency:
The time to repair is reduced from 333s to 0.2s.
333.26758 s / 0.22625381s = 1472.98
3)
3 DCs, each DC has 3 nodes, 9 nodes in the cluster. RF = {dc1: 3, dc2: 3, dc3: 3}
, 10 ms network latency
Before:
```
repair - repair[86124a4a-fd26-42ea-a078-437ca9e372df]: stats:
repair_reason=repair, keyspace=system_auth, tables={role_attributes,
role_members, roles}, ranges_nr=2305, round_nr=6916,
round_nr_fast_path_already_synced=6915,
round_nr_fast_path_same_combined_hashes=0, round_nr_slow_path=1,
rpc_call_nr=276630, tx_hashes_nr=0, rx_hashes_nr=8, duration=986.34015
seconds, tx_row_nr=7, rx_row_nr=0, tx_row_bytes=1246, rx_row_bytes=0,
row_from_disk_bytes={{127.0.57.1, 178}, {127.0.57.2, 178}, {127.0.57.3,
0}, {127.0.57.4, 0}, {127.0.57.5, 0}, {127.0.57.6, 0}, {127.0.57.7, 0},
{127.0.57.8, 0}, {127.0.57.9, 0}}, row_from_disk_nr={{127.0.57.1, 1},
{127.0.57.2, 1}, {127.0.57.3, 0}, {127.0.57.4, 0}, {127.0.57.5, 0},
{127.0.57.6, 0}, {127.0.57.7, 0}, {127.0.57.8, 0}, {127.0.57.9, 0}},
row_from_disk_bytes_per_sec={{127.0.57.1, 1.72105e-07}, {127.0.57.2,
1.72105e-07}, {127.0.57.3, 0}, {127.0.57.4, 0}, {127.0.57.5, 0},
{127.0.57.6, 0}, {127.0.57.7, 0}, {127.0.57.8, 0}, {127.0.57.9, 0}}
MiB/s, row_from_disk_rows_per_sec={{127.0.57.1, 0.00101385},
{127.0.57.2, 0.00101385}, {127.0.57.3, 0}, {127.0.57.4, 0},
{127.0.57.5, 0}, {127.0.57.6, 0}, {127.0.57.7, 0}, {127.0.57.8, 0},
{127.0.57.9, 0}} Rows/s, tx_row_nr_peer={{127.0.57.3, 1},
{127.0.57.4, 1}, {127.0.57.5, 1}, {127.0.57.6, 1}, {127.0.57.7, 1},
{127.0.57.8, 1}, {127.0.57.9, 1}}, rx_row_nr_peer={}
```
After:
```
repair - repair[07ebd571-63cb-4ef6-9465-6e5f1e98f04f]: stats:
repair_reason=repair, keyspace=system_auth, tables={role_attributes,
role_members, roles}, ranges_nr=1, round_nr=4,
round_nr_fast_path_already_synced=4,
round_nr_fast_path_same_combined_hashes=0, round_nr_slow_path=0,
rpc_call_nr=128, tx_hashes_nr=0, rx_hashes_nr=0, duration=1.6052915
seconds, tx_row_nr=0, rx_row_nr=0, tx_row_bytes=0, rx_row_bytes=0,
row_from_disk_bytes={{127.0.57.1, 178}, {127.0.57.2, 178}, {127.0.57.3,
178}, {127.0.57.4, 178}, {127.0.57.5, 178}, {127.0.57.6, 178},
{127.0.57.7, 178}, {127.0.57.8, 178}, {127.0.57.9, 178}},
row_from_disk_nr={{127.0.57.1, 1}, {127.0.57.2, 1}, {127.0.57.3, 1},
{127.0.57.4, 1}, {127.0.57.5, 1}, {127.0.57.6, 1}, {127.0.57.7, 1},
{127.0.57.8, 1}, {127.0.57.9, 1}},
row_from_disk_bytes_per_sec={{127.0.57.1, 0.00037793}, {127.0.57.2,
0.00037793}, {127.0.57.3, 0.00037793}, {127.0.57.4, 0.00037793},
{127.0.57.5, 0.00037793}, {127.0.57.6, 0.00037793}, {127.0.57.7,
0.00037793}, {127.0.57.8, 0.00037793}, {127.0.57.9, 0.00037793}}
MiB/s, row_from_disk_rows_per_sec={{127.0.57.1, 2.22634},
{127.0.57.2, 2.22634}, {127.0.57.3, 2.22634}, {127.0.57.4,
2.22634}, {127.0.57.5, 2.22634}, {127.0.57.6, 2.22634},
{127.0.57.7, 2.22634}, {127.0.57.8, 2.22634}, {127.0.57.9,
2.22634}} Rows/s, tx_row_nr_peer={}, rx_row_nr_peer={}
```
The time to repair is reduced from 986s (16 minutes) to 1.6s
*) Summary
So, a more than 1000X difference is observed for this common usage of
system table repair procedure.
Fixes#16011
Refs #15159
Before integration with task manager the state of one shard repair
was kept in repair_info. repair_info object was destroyed immediately
after shard repair was finished.
In an integration process repair_info's fields were moved to
shard_repair_task_impl as the two served the similar purposes.
Though, shard_repair_task_impl isn't immediately destoyed, but is
kept in task manager for task_ttl seconds after it's complete.
Thus, some of repair_info's fields have their lifetime prolonged,
which makes the repair state change delayed.
Release shard_repair_task_impl resources immediately after shard
repair is finished.
Fixes: #15505.
Closesscylladb/scylladb#15506
Most of the time only the roots of tasks tree should be non internal.
Change default implementation of is_internal and delete overrides
consistent with it.
Closesscylladb/scylladb#15353
Node operations will be integrated with task manager and so node_ops
directory needs to be created. To have an access to node ops related
classes from task manager and preserve consistent naming, move
the classes to node_ops/node_ops_data.cc.
Override methods returning expected children number and job size
in repair tasks. With them get_progress method would be able to
return more precise progress value.
Getting reason argument in task_manager_module::get_progress is deceiving
as the method works properly only for streaming::stream_reason::repair
(repair::shard_repair_task_impl::nr_ranges_finished isn't updated for
any other reason).
This patch adds the ranges_parallelism option to repair restful API.
Users can use this option to optionally specify the number of ranges
to repair in parallel per repair job to a smaller number than the Scylla
core calculated default max_repair_ranges_in_parallel.
Scylla manager can also use this option to provide more ranges (>N) in
a single repair job but only repairing N ranges_parallelism in parallel,
instead of providing N ranges in a repair job.
To make it safer, unlike the PR #4848, this patch does not allow user to
exceed the max_repair_ranges_in_parallel.
Fixes#4847
Instead of just a boolean _failed flag, persist the error message of the
exception which caused the repair to fail, and include it in the log
message announcing the failure.
This helps users to figure if the repair has failed due to a peer node
was down during repair.
For example:
```
WARN [shard 0] repair - repair[ec2e9646-918e-4345-99ab-fa07aa1f17de]: Repair
1026 out of 1026 ranges, keyspace=ks2a, table={test_table, tb},
range=(9203128250168517738,+inf), peers={127.0.0.2}, live_peers={},
status=skipped_no_live_peers
INFO [shard 0] repair - repair[ec2e9646-918e-4345-99ab-fa07aa1f17de]: stats:
repair_reason=repair, keyspace=ks2a, tables={test_table, tb}, ranges_nr=513,
round_nr=0, round_nr_fast_path_already_synced=0,
round_nr_fast_path_same_combined_hashes=0, round_nr_slow_path=0, rpc_call_nr=0,
tx_hashes_nr=0, rx_hashes_nr=0, duration=0 seconds, tx_row_nr=0, rx_row_nr=0,
tx_row_bytes=0, rx_row_bytes=0, row_from_disk_bytes={}, row_from_disk_nr={},
row_from_disk_bytes_per_sec={} MiB/s, row_from_disk_rows_per_sec={} Rows/s,
tx_row_nr_peer={}, rx_row_nr_peer={}
WARN [shard 0] repair - repair[ec2e9646-918e-4345-99ab-fa07aa1f17de]: 1026 out
of 1026 ranges failed, keyspace=ks2a, tables={test_table, tb},
repair_reason=repair, nodes_down_during_repair={127.0.0.2}
WARN [shard 0] repair - repair[ec2e9646-918e-4345-99ab-fa07aa1f17de]:
repair_tracker run failed: std::runtime_error ({shard 0: std::runtime_error
(repair[ec2e9646-918e-4345-99ab-fa07aa1f17de]: 1026 out of 1026 ranges failed,
keyspace=ks2a, tables={test_table, tb}, repair_reason=repair,
nodes_down_during_repair={127.0.0.2})})
```
In addition, change the `status=skipped` to `status=skipped_no_live_peers`
to make it more clear.
Closes#13928
